# What is the easiest algorithm to find the day of week of day zero of a given year?

I am trying to figure out what the day of the week of day zero (January 1st) of a given year.

So far I have looked at the Wikipedia page 'Calculating the day of the week' but I was wondering if there is an easiest algorithm if you're just trying to find day zero.

• Are you asking for the calendar to become somehow simpler than it is? Jan 26 '09 at 2:34
• I think this is the first time I've heard of 1st January being called 'day zero'; most people call it 'day one' of the year. Jan 26 '09 at 5:16
• Yeah I'm not to keen on day-zero either, anyways... Jan 26 '09 at 8:32
• Starting counting at zero. Yep, must be a programmer :-). "So, who's going to the party?" "Alice, Bob and me. Let's see, that's 0, 1, 2. Yes, two people." Feb 15 '09 at 15:41

Here's a simple one-liner. I've verified this for all the years 1901-2200 using Excel, and 1582-3000 using Python's `datetime`.

``````dayOfWeek = (year*365 + trunc((year-1) / 4) - trunc((year-1) / 100) +
trunc((year-1) / 400)) % 7
``````

This will give the day of the week as 0 = Sunday, 6 = Saturday. This result can easily be adjusted by adding a constant before or after the modulo 7. For example to match Python's convention of 0 = Monday, add 6 before the modulo.

• I think you can change `year*365` to `year` because 365 mod 7 = 1. It would be `dayOfWeek = (year + trunc((year-1) / 4) - trunc((year-1) / 100) + trunc((year-1) / 400)) % 7` Apr 14 '20 at 6:27
• @PiyapanPoomsirivilai there's probably 100 ways to optimize this formula, but I wasn't trying to do that. I wanted something that was easy to understand from basic principles. You're basically calculating a day number by assuming each year is 365 days, then adding all of the leap days too. Apr 14 '20 at 15:38
``````int dayofweek(y, m, d)      /* 0 = Sunday */
int y, m, d;                /* 1 <= m <= 12,  y > 1752 or so */
{
static int t[] = {0, 3, 2, 5, 0, 3, 5, 1, 4, 6, 2, 4};
y -= m < 3;
return (y + y/4 - y/100 + y/400 + t[m-1] + d) % 7;
}
``````
• +1 as I like the conciseness of this, even though the magic numbers are naughty - how did you calculate them and why the uncertainty for pre 1752 dates? Oct 16 '12 at 22:18
• @jacanterbury: 1752 was when British territories (such as what is now the USA) switched from Julian to Gregorian calendar, losing 11 days — 3-13 September — in the process). Other areas of the world changed as early as 1584 (working from memory) and others not until the 20th Century (which is why the October Revolution in Russia occurred in November in most of the rest of the world), and quite a lot of different dates in between. You can even find that Sweden had a 30th of February 1712 because of the switchover (and mistakes made during the switchover). Apr 21 '14 at 7:07
• Feb 3 '18 at 9:12
• This algorithm is likely attributable to Sakamoto, see en.wikipedia.org/wiki/Determination_of_the_day_of_the_week. However the OP requested only how to determine the day of the week for Jan 1 of a given year. In this case the "t" array and the m and d parameters can be eliminated. The rest of the subroutine gets the obvious resulting adjustments. Mar 18 at 17:12

Most languages provide facilities for representing and manipulating dates... I would rely on those instead of implementing some (probably incomplete) algorithm.

• Assuming "the language" is Standard C, it isn't particularly trivial to make it tell you the day of the week of an arbitrary date. It can be done - it is not particularly simple to do so. Jan 26 '09 at 5:18
• Good idea if the language has it. Doesn't work worth a hill of beans if you are bootstrapping
– BCS
May 25 '09 at 17:30
• In an embedded environment (where you're trying to save on space) this assumption basically goes out the window...
– alex
Dec 21 '11 at 9:10
• Saying "use an existing implementation" is not the right answer if a user asks for an algorithm. Feb 11 '13 at 14:02
``````day = (((year - 1) * 365) + ((year - 1) / 4) - ((year - 1) / 100) + ((year) / 400) + 1) % 7;
``````

Given the year, this will find the day of the week for January 1, where Sunday is 0 and Saturday is 6

• +1 because this actually answer the OP's question (he wanted a result only for January 1 of a given year). This could be called an adaption of nikhil's answer (with the obvious adjustments for January 1), although that answer probably should have been attributed to Sakamoto. See en.wikipedia.org/wiki/Determination_of_the_day_of_the_week Mar 18 at 17:47
``````public String DayOfWeek()
{
int dayofweek;
int c,y,m,d;
int cc,yy;
String dayString;
//Im using the guassian algorithm for finding day of the week
cc = year/100;
yy = year - ((year/100)*100);

c = (cc/4) - 2*cc-1;
y = 5*yy/4;
m = 26*(month+1)/10;
d = day;

dayofweek = (c+y+m+d)%7;

switch(dayofweek)
{
case 0: dayString = "Sunday";
break;
case 1: dayString = "Monday";
break;
case 2: dayString = "Tuesday";
break;
case 3: dayString = "Wednesday";
break;
case 4: dayString = "Thursday";
break;
case 5: dayString = "Friday";
break;
case 6: dayString = "Saturday";
break;
default: dayString = "Sorry Could not compute month :(";
}

return dayString;
}
``````

The code above is written in Java

not sure why it works but i found that algorithm deep in the bowels of a Google search and quickly jumped on it for my project. what you see above is a method i had to write for a project i was doing in my java class in college, so it was written by me, but the algorithm is not my own.

this method is guaranteed to work 100% if the time, i've tried multiple days throughout history and looked them up to confirm the correct answer was the one that was found by this method.

Let the date be DD/MM/CCYY (european format), where DD is the day of the month, MM is the month, CC the century-digits and YY the year within the century. So Wilma's birthday was 23/06/1994. Starting with the century CC-digits, calculate CC/4 - 2*CC-1 and remember the result. With all divisions in this exercise, discard any remainder and just keep the whole part. So, in our example, this is 19/4=4 minus 2*19=38 minus 1, giving minus 35.

Now, using the year YY, calculate 5*YY/4. In this example that's 5*94 = 470/4 = 117, discarding the remainder. Adding this to our existing result gives 117-35 = 82.

Using the month MM, calculate 26*(MM+1)/10. In our example this is 26*7 = 182 / 10 = 18, again discarding the remainder. Add this to our running total giving 82+18 = 100.

Finally just add the day DD. Here 100 + 23 = 123.

Now divide the result by 7, just keeping the remainder; here 123(mod 7) = 4. Counting Sunday as zero, Monday = 1 etc, we get 4 = Thursday. Easy, when you know how :-)

The algorithm is attributed to Gauss. Yes, I do know that Jews and Muslims etc have different calenders and I do know about the various calender reforms, so this only applies to the modern Christian-based standardised dates, don't go using it to check the day of Christ's crucifixion (-fiction?) or even Chaucer's birth.

If you can't do this as mental arithmetic (thus winning beers in the pub) feel free to use pencil and paper (or a calculator).

• An explanation would improve your answer. Oct 6 '12 at 9:05
• i dont even know how it works i just googled the gaussian method and thats what i found. basically it just breaks down the date into different numbers and uses those different numbers to calculate the day of the week Nov 14 '12 at 2:04
• What is this part?? `yy = year - ((year/100)*100);` May 11 '16 at 9:45
• if year is an integer, then yy = year - ((year/100)*100) is the same as yy = year % 100 Feb 9 '17 at 19:22
``````     #!/usr/local/bin/perl
use integer
%day=                 (0=>Sunday,1=>Monday,2=>Tuesday,3=>Wednesday,4=>Thursday,5=>Friday,6=>Saturday);
print("entered date is");
\$day=30;
\$month=11;
\$year=2680;
\$x=&day_of_week(\$year,\$month,\$day);
if(\$day>31||\$month>12)
{
print("this date doesn't exist \n");
exit;
}

if(\$year%400 ==0 || (\$year%100 != 0 && \$year%4 == 0))
{
if(\$day>29&&\$month==2)
{
printf("this date dosen't exist \n");
exit;
}
}
if(\$month==(4,6,9,11)&&\$day>30)
{
printf("this date dosen't exist \n");
exit;
}

sub day_of_week{
my (\$year,\$month,\$day)=@_;
print("yy/mm/dd: \$year/\$month/\$day\n");
my  \$a=(14-\$month)/12;
my  \$y=\$year-\$a;
my  \$m=\$month+12*\$a-2;
my  \$d=(\$day+\$y+\$y/4-\$y/100+\$y/400+31*\$m/12)%7;
return \$d;
}
if(exists(\$day{\$x}))
{
print("\$day{\$x}\n");
}
else
{
print("invalid date entered\n");
}
``````

MATLAB routine:

function w = week_day(m,d,cy)

if m > 2, m = m-2; else, m = m+10; cy = cy-1; end;

c = fix(cy/100); y = mod(cy,100);

w = mod(d+fix(m*2.59)+fix(y*1.25)+fix(c*5.25),7);

The trick is to put March 1st as the first day of the year. Regardless to know if the date is in the leap year or not.

Examples:

``````   w = week_day(01,23,2016)  --->   w = 6 {Sat)    Today
w = week_day(12,31,1999)  --->   w = 5 {Fri)
w = week_day(01,01,2000)  --->   w = 6 {Sat)
w = week_day(02,28,1900)  --->   w = 3 {Wed)    not leap year
w = week_day(03,01,1900)  --->   w = 4 {Thu)
w = week_day(02,29,2000)  --->   w = 2 {Tue)      leap year
w = week_day(03,01,2000)  --->   w = 3 {Wed)
``````

Please refer Mathwork File Exchange File ID #54784

Feng Cheng Chang

The bottom of the Wikipedia page on "Calculating the day of the week" gives the rules you'd need. You could also simplify Zeller's congruence by hardcoding the month and day of the month.

Years repeat on a 28 year cycle. Divide the year by 28 and return the respective day-of-the-week (the day-of-the-week values being stored in an array/vector). This would be the fastest and simplest algorithm. But this algorithm would not be at all clear to someone reading the code. Your choice depends on whether you want fast, simple or "clearly correct".

• Thanks, that was perfect for what I needed. Jan 26 '09 at 3:13
• Yeah, I vaguely remember there's some strange days or other added every once in a while. I suppose we might have a year 2400 problem. Jan 26 '09 at 3:29
• Years divisible by 100 are only leap years if they've divisible by 400. Hence 2000 and 2400 are leap years, but 1900 and 2100 aren't. Jan 26 '09 at 3:41
• Sorry, have to -1 as I was bitten by the rule Nikhil gave in 2000. Not enough people know the full definition of a leap year! Jan 26 '09 at 4:43
• Right - so the 28 year thing will only work until 2100 then (and it worked over 2000 because of the 400 year rule.) Jan 26 '09 at 4:51

If date is DD/MM/CCYY and you need to calculate day of the given date. Then use the given formula [{(CC/4)-2*CC -1}+(YY*5/4)+{(MM+1)*26/10} + DD]= x, x/7=Y where Y is the remainder where Y can be 0,1,2,3,4,5,6. where 0 can be reffered as sunday, 1 is monday, 2 is tuesday , 3 is wednesday etc.

• Must remember that always discard the remainder in given formula or while calculating the x Jan 16 '14 at 13:26

You could always keep a reference date, and then add days of the year (mod 7) to keep a running tally, but like Zach said, using built-in functions is going to be way easier.

• You've fotten leap-a-year here. It's 28, not 7, due to this. Jan 26 '09 at 2:57
• Actually its a 400 * 7 = 2800 year cycle. See Nikhil's comment on Joe's answer. Jan 26 '09 at 4:47
• I meant adding 365 (or 366), then doing mod 7. It's accurate as long as you can predict leap years. Jan 26 '09 at 5:00
• @j_random_hacker: Actually, there are exactly (365*400+97)/7 = 20871 weeks in 400 years, so the 400 year cycle repeats exactly without needing to jump to a 2,800 year cycle. If 400 years was not an exact number of weeks, you'd be right. Jan 26 '09 at 5:14